AI Article Synopsis
- There is a need to increase the reverse intersystem crossing rate constant (k) in thermally activated delayed fluorescence (TADF) materials for better performance in organic light-emitting diodes (OLEDs).
- Recent findings suggest that matching energy levels between locally excited (LE) states and charge transfer (CT) states can enhance k, but this study shows that k can improve even between different CT states without LE involvement.
- The new compound DMAC-bPmT, designed by replacing phenyl groups in DMAC-TRZ with pyrimidine groups, demonstrated a threefold increase in k thanks to its closely positioned CT states and enhanced spin-orbit coupling.
Article Abstract
There is a need to boost the rate constant of reverse intersystem crossing (k ) in thermally activated delayed fluorescence (TADF) materials for applications to organic light-emitting diodes. Recently, energy level matching of the locally excited state (LE) and charge transfer state (CT) has been reported to enhance k . In this study, we conceptually demonstrate that k can be improved even between CT states without LE states, through the use of different types of CT states. On the basis of this concept, we design a new compound, named DMAC-bPmT, where two phenyl groups of a well-known TADF material DMAC-TRZ are substituted by pyrimidine groups. Theoretical calculations indicated that the energy levels of the different CT states of DMAC-bPmT are very close and enhanced spin orbit coupling may be expected between them. As predicted, DMAC-bPmT experimentally exhibited a k three times as high as that of DMAC-TRZ.
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| http://dx.doi.org/10.1002/asia.202100091 | DOI Listing |
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